-(* Copyright (C) 2000, HELM Team.
+(* Copyright (C) 2003-2005, HELM Team.
*
* This file is part of HELM, an Hypertextual, Electronic
* Library of Mathematics, developed at the Computer Science
module P = Mpresentation
module B = Box
+module Con = Content
let p_mtr a b = Mpresentation.Mtr(a,b)
let p_mtd a b = Mpresentation.Mtd(a,b)
else let l1,l2 =
split (n-1) (List.tl l) in
(List.hd l)::l1,l2
-;;
-
-let is_big_general countterm p =
- let maxsize = Ast2pres.maxsize in
- let module Con = Content in
- let rec countp current_size p =
- if current_size > maxsize then current_size
- else
- let c1 = (countcontext current_size p.Con.proof_context) in
- if c1 > maxsize then c1
- else
- let c2 = (countapplycontext c1 p.Con.proof_apply_context) in
- if c2 > maxsize then c2
- else
- countconclude c2 p.Con.proof_conclude
-
- and
- countcontext current_size c =
- List.fold_left countcontextitem current_size c
- and
- countcontextitem current_size e =
- if current_size > maxsize then maxsize
- else
- (match e with
- `Declaration d ->
- (match d.Con.dec_name with
- Some s -> current_size + 4 + (String.length s)
- | None -> prerr_endline "NO NAME!!"; assert false)
- | `Hypothesis h ->
- (match h.Con.dec_name with
- Some s -> current_size + 4 + (String.length s)
- | None -> prerr_endline "NO NAME!!"; assert false)
- | `Proof p -> countp current_size p
- | `Definition d ->
- (match d.Con.def_name with
- Some s ->
- let c1 = (current_size + 4 + (String.length s)) in
- (countterm c1 d.Con.def_term)
- | None ->
- prerr_endline "NO NAME!!"; assert false)
- | `Joint ho -> maxsize + 1) (* we assume is big *)
- and
- countapplycontext current_size ac =
- List.fold_left countp current_size ac
- and
- countconclude current_size co =
- if current_size > maxsize then current_size
- else
- let c1 = countargs current_size co.Con.conclude_args in
- if c1 > maxsize then c1
- else
- (match co.Con.conclude_conclusion with
- Some concl -> countterm c1 concl
- | None -> c1)
- and
- countargs current_size args =
- List.fold_left countarg current_size args
- and
- countarg current_size arg =
- if current_size > maxsize then current_size
- else
- (match arg with
- Con.Aux _ -> current_size
- | Con.Premise prem ->
- (match prem.Con.premise_binder with
- Some s -> current_size + (String.length s)
- | None -> current_size + 7)
- | Con.Lemma lemma ->
- current_size + (String.length lemma.Con.lemma_name)
- | Con.Term t -> countterm current_size t
- | Con.ArgProof p -> countp current_size p
- | Con.ArgMethod s -> (maxsize + 1)) in
- let size = (countp 0 p) in
- (size > maxsize)
-;;
-
-let is_big = is_big_general (Ast2pres.countterm)
-;;
-
-let get_xref =
- let module Con = Content in
- function
- `Declaration d
- | `Hypothesis d -> d.Con.dec_id
- | `Proof p -> p.Con.proof_id
- | `Definition d -> d.Con.def_id
- | `Joint jo -> jo.Con.joint_id
-;;
-
-let make_row ?(attrs=[]) items concl =
- match concl with
- B.V _ -> (* big! *)
+let get_xref = function
+ | `Declaration d
+ | `Hypothesis d -> d.Con.dec_id
+ | `Proof p -> p.Con.proof_id
+ | `Definition d -> d.Con.def_id
+ | `Joint jo -> jo.Con.joint_id
+
+let hv_attrs =
+ RenderingAttrs.spacing_attributes `BoxML
+ @ RenderingAttrs.indent_attributes `BoxML
+
+let make_row items concl =
+ B.b_hv hv_attrs (items @ [ concl ])
+(* match concl with
+ B.V _ -> |+ big! +|
B.b_v attrs [B.b_h [] items; B.b_indent concl]
- | _ -> (* small *)
- B.b_h attrs (items@[B.b_space; concl])
-;;
+ | _ -> |+ small +|
+ B.b_h attrs (items@[B.b_space; concl]) *)
let make_concl ?(attrs=[]) verb concl =
- match concl with
- B.V _ -> (* big! *)
+ B.b_hv (hv_attrs @ attrs) [ B.b_kw verb; concl ]
+(* match concl with
+ B.V _ -> |+ big! +|
B.b_v attrs [ B.b_kw verb; B.b_indent concl]
- | _ -> (* small *)
- B.b_h attrs [ B.b_kw verb; B.b_space; concl ]
-;;
+ | _ -> |+ small +|
+ B.b_h attrs [ B.b_kw verb; B.b_space; concl ] *)
let make_args_for_apply term2pres args =
- let module Con = Content in
let make_arg_for_apply is_first arg row =
let res =
match arg with
| Some s -> s) in
(B.b_object (P.Mi ([], name)))::row
| Con.Lemma lemma ->
- (B.b_object (P.Mi([],lemma.Con.lemma_name)))::row
+ let lemma_attrs = [
+ Some "helm", "xref", lemma.Con.lemma_id;
+ Some "xlink", "href", lemma.Con.lemma_uri ]
+ in
+ (B.b_object (P.Mi(lemma_attrs,lemma.Con.lemma_name)))::row
| Con.Term t ->
if is_first then
(term2pres t)::row
make_arg_for_apply true hd
(List.fold_right (make_arg_for_apply false) tl [])
| _ -> assert false
-;;
let get_name = function
| Some s -> s
| None -> "_"
+let add_xref id = function
+ | B.Text (attrs, t) -> B.Text (((Some "helm", "xref", id) :: attrs), t)
+ | _ -> assert false (* TODO, add_xref is meaningful for all boxes *)
+
let rec justification term2pres p =
- let module Con = Content in
- let module P = Mpresentation in
if ((p.Con.proof_conclude.Con.conclude_method = "Exact") or
((p.Con.proof_context = []) &
(p.Con.proof_apply_context = []) &
and proof2pres term2pres p =
let rec proof2pres p =
- let module Con = Content in
- let indent =
- let is_decl e =
- (match e with
- `Declaration _
- | `Hypothesis _ -> true
- | _ -> false) in
- ((List.filter is_decl p.Con.proof_context) != []) in
- let omit_conclusion = (not indent) && (p.Con.proof_context != []) in
- let concl =
- (match p.Con.proof_conclude.Con.conclude_conclusion with
- None -> None
- | Some t -> Some (term2pres t)) in
- let body =
- let presconclude =
- conclude2pres p.Con.proof_conclude indent omit_conclusion in
- let presacontext =
- acontext2pres p.Con.proof_apply_context presconclude indent in
- context2pres p.Con.proof_context presacontext in
- match p.Con.proof_name with
- None -> body
- | Some name ->
- let action =
- match concl with
- None -> body
- | Some ac ->
- B.Action
- ([None,"type","toggle"],
- [(make_concl ~attrs:[Some "helm", "xref", p.Con.proof_id]
- "proof of" ac); body])
- in
- B.V ([],
- [B.Text ([],"(" ^ name ^ ")");
- B.indent action])
+ let indent =
+ let is_decl e =
+ (match e with
+ `Declaration _
+ | `Hypothesis _ -> true
+ | _ -> false) in
+ ((List.filter is_decl p.Con.proof_context) != []) in
+ let omit_conclusion = (not indent) && (p.Con.proof_context != []) in
+ let concl =
+ (match p.Con.proof_conclude.Con.conclude_conclusion with
+ None -> None
+ | Some t -> Some (term2pres t)) in
+ let body =
+ let presconclude =
+ conclude2pres p.Con.proof_conclude indent omit_conclusion in
+ let presacontext =
+ acontext2pres p.Con.proof_apply_context presconclude indent in
+ context2pres p.Con.proof_context presacontext in
+ match p.Con.proof_name with
+ None -> body
+ | Some name ->
+ let action =
+ match concl with
+ None -> body
+ | Some ac ->
+ B.Action
+ ([None,"type","toggle"],
+ [(make_concl ~attrs:[Some "helm", "xref", p.Con.proof_id]
+ "proof of" ac); body])
+ in
+ B.V ([],
+ [B.Text ([],"(" ^ name ^ ")");
+ B.indent action])
and context2pres c continuation =
(* we generate a subtable for each context element, for selection
(fun ce continuation ->
let xref = get_xref ce in
B.V([Some "helm", "xref", xref ],
- [B.H([Some "helm", "xref", "ce_"^xref],[ce2pres ce]);
+ [B.H([Some "helm", "xref", "ce_"^xref],
+ [ce2pres_in_proof_context_element ce]);
continuation])) tl continuation in
let hd_xref= get_xref hd in
B.V([],
[B.H([Some "helm", "xref", "ce_"^hd_xref],
- [ce2pres hd]);
+ [ce2pres_in_proof_context_element hd]);
continuation'])
-
- and ce2pres =
- let module Con = Content in
- function
+
+ and ce2pres_in_joint_context_element = function
+ | `Inductive _ -> assert false (* TODO *)
+ | (`Declaration _) as x -> ce2pres x
+ | (`Hypothesis _) as x -> ce2pres x
+ | (`Proof _) as x -> ce2pres x
+ | (`Definition _) as x -> ce2pres x
+
+ and ce2pres_in_proof_context_element = function
+ | `Joint ho ->
+ B.H ([],(List.map ce2pres_in_joint_context_element ho.Content.joint_defs))
+ | (`Declaration _) as x -> ce2pres x
+ | (`Hypothesis _) as x -> ce2pres x
+ | (`Proof _) as x -> ce2pres x
+ | (`Definition _) as x -> ce2pres x
+
+ and ce2pres =
+ function
`Declaration d ->
(match d.Con.dec_name with
Some s ->
Some s ->
let term = term2pres d.Con.def_term in
B.H ([],
- [B.Text([],"Let ");
- B.Object ([], P.Mi([],s));
- B.Text([]," = ");
- term])
+ [ B.b_kw "Let"; B.b_space;
+ B.Object ([], P.Mi([],s));
+ B.Text([]," = ");
+ term])
| None ->
prerr_endline "NO NAME!!"; assert false)
- | `Joint ho ->
- B.Text ([],"jointdef")
and acontext2pres ac continuation indent =
- let module Con = Content in
List.fold_right
(fun p continuation ->
let hd =
continuation])) ac continuation
and conclude2pres conclude indent omit_conclusion =
- let module Con = Content in
- let module P = Mpresentation in
let tconclude_body =
match conclude.Con.conclude_conclusion with
Some t when
else
B.H ([Some "helm", "xref", conclude.Con.conclude_id],[tconclude_body])
-
and conclude_aux conclude =
- let module Con = Content in
- let module P = Mpresentation in
if conclude.Con.conclude_method = "TD_Conversion" then
let expected =
(match conclude.Con.conclude_conclusion with
let arg =
(match conclude.Con.conclude_args with
[Con.Term t] -> term2pres t
- | _ -> assert false) in
+ | [Con.Premise p] ->
+ (match p.Con.premise_binder with
+ | None -> assert false; (* unnamed hypothesis ??? *)
+ | Some s -> B.Text([],s))
+ | err -> assert false) in
(match conclude.Con.conclude_conclusion with
None ->
B.b_h [] [B.b_kw "Consider"; B.b_space; arg]
| Some c -> let conclusion = term2pres c in
make_row
- [arg; B.b_space; B.Text([],"proves")]
+ [arg; B.b_space; B.b_kw "proves"]
conclusion
)
else if conclude.Con.conclude_method = "Intros+LetTac" then
B.b_space::
B.Text([],"(")::pres_args@[B.Text([],")")])
else
- B.V
- ([],
- [B.Text([],"Apply method" ^ conclude.Con.conclude_method ^ " to");
- (B.indent
- (B.V
- ([],
- args2pres conclude.Con.conclude_args)))])
+ B.V ([], [
+ B.b_kw ("Apply method" ^ conclude.Con.conclude_method ^ " to");
+ (B.indent (B.V ([], args2pres conclude.Con.conclude_args)))])
and args2pres l = List.map arg2pres l
and arg2pres =
- let module Con = Content in
function
- Con.Aux n ->
- B.Text ([],"aux " ^ n)
- | Con.Premise prem ->
- B.Text ([],"premise")
- | Con.Lemma lemma ->
- B.Text ([],"lemma")
- | Con.Term t ->
- term2pres t
- | Con.ArgProof p ->
- proof2pres p
- | Con.ArgMethod s ->
- B.Text ([],"method")
+ Con.Aux n -> B.b_kw ("aux " ^ n)
+ | Con.Premise prem -> B.b_kw "premise"
+ | Con.Lemma lemma -> B.b_kw "lemma"
+ | Con.Term t -> term2pres t
+ | Con.ArgProof p -> proof2pres p
+ | Con.ArgMethod s -> B.b_kw "method"
and case conclude =
- let module Con = Content in
let proof_conclusion =
(match conclude.Con.conclude_conclusion with
- None -> B.Text([],"No conclusion???")
+ None -> B.b_kw "No conclusion???"
| Some t -> term2pres t) in
let arg,args_for_cases =
(match conclude.Con.conclude_args with
let case_on =
let case_arg =
(match arg with
- Con.Aux n ->
- B.Text ([],"an aux???")
+ Con.Aux n -> B.b_kw "an aux???"
| Con.Premise prem ->
(match prem.Con.premise_binder with
- None -> B.Text ([],"the previous result")
+ None -> B.b_kw "the previous result"
| Some n -> B.Object ([], P.Mi([],n)))
| Con.Lemma lemma -> B.Object ([], P.Mi([],lemma.Con.lemma_name))
| Con.Term t ->
term2pres t
- | Con.ArgProof p ->
- B.Text ([],"a proof???")
- | Con.ArgMethod s ->
- B.Text ([],"a method???")) in
- (make_concl "we proceede by cases on" case_arg) in
+ | Con.ArgProof p -> B.b_kw "a proof???"
+ | Con.ArgMethod s -> B.b_kw "a method???")
+ in
+ (make_concl "we proceed by cases on" case_arg) in
let to_prove =
(make_concl "to prove" proof_conclusion) in
- B.V
- ([],
- case_on::to_prove::(make_cases args_for_cases))
+ B.V ([], case_on::to_prove::(make_cases args_for_cases))
and byinduction conclude =
- let module Con = Content in
let proof_conclusion =
(match conclude.Con.conclude_conclusion with
- None -> B.Text([],"No conclusion???")
+ None -> B.b_kw "No conclusion???"
| Some t -> term2pres t) in
let inductive_arg,args_for_cases =
(match conclude.Con.conclude_args with
let induction_on =
let arg =
(match inductive_arg with
- Con.Aux n ->
- B.Text ([],"an aux???")
+ Con.Aux n -> B.b_kw "an aux???"
| Con.Premise prem ->
(match prem.Con.premise_binder with
- None -> B.Text ([],"the previous result")
+ None -> B.b_kw "the previous result"
| Some n -> B.Object ([], P.Mi([],n)))
| Con.Lemma lemma -> B.Object ([], P.Mi([],lemma.Con.lemma_name))
| Con.Term t ->
term2pres t
- | Con.ArgProof p ->
- B.Text ([],"a proof???")
- | Con.ArgMethod s ->
- B.Text ([],"a method???")) in
- (make_concl "we proceede by induction on" arg) in
+ | Con.ArgProof p -> B.b_kw "a proof???"
+ | Con.ArgMethod s -> B.b_kw "a method???") in
+ (make_concl "we proceed by induction on" arg) in
let to_prove =
(make_concl "to prove" proof_conclusion) in
- B.V
- ([],
- induction_on::to_prove::
- (make_cases args_for_cases))
+ B.V ([], induction_on::to_prove:: (make_cases args_for_cases))
and make_cases l = List.map make_case l
and make_case =
- let module Con = Content in
function
Con.ArgProof p ->
let name =
(match p.Con.proof_name with
- None -> B.Text([],"no name for case!!")
+ None -> B.b_kw "no name for case!!"
| Some n -> B.Object ([], P.Mi([],n))) in
let indhyps,args =
List.partition
dec@p) args [] in
let pattern =
B.H ([],
- (B.Text([],"Case")::B.b_space::name::pattern_aux)@
+ (B.b_kw "Case"::B.b_space::name::pattern_aux)@
[B.b_space;
- B.Text([],"->")]) in
+ B.Text([], Utf8Macro.unicode_of_tex "\\Rightarrow")]) in
let subconcl =
(match p.Con.proof_conclude.Con.conclude_conclusion with
- None -> B.Text([],"No conclusion!!!")
+ None -> B.b_kw "No conclusion!!!"
| Some t -> term2pres t) in
let asubconcl = B.indent (make_concl "the thesis becomes" subconcl) in
let induction_hypothesis =
(match indhyps with
[] -> []
| _ ->
- let text =
- B.indent (B.Text([],"by induction hypothesis we know:")) in
+ let text = B.indent (B.b_kw "by induction hypothesis we know") in
let make_hyp =
function
`Hypothesis h ->
| {Con.proof_id = id}::_ -> id
in
B.Action([None,"type","toggle"],
- [B.indent
- (B.Text
- ([None,"color","red" ;
- Some "helm", "xref", acontext_id],"Proof")) ;
- acontext2pres p.Con.proof_apply_context body true]) in
+ [ B.indent (add_xref acontext_id (B.b_kw "Proof"));
+ acontext2pres p.Con.proof_apply_context body true]) in
B.V ([], pattern::asubconcl::induction_hypothesis@[presacontext])
| _ -> assert false
and falseind conclude =
- let module P = Mpresentation in
- let module Con = Content in
let proof_conclusion =
(match conclude.Con.conclude_conclusion with
- None -> B.Text([],"No conclusion???")
+ None -> B.b_kw "No conclusion???"
| Some t -> term2pres t) in
let case_arg =
(match conclude.Con.conclude_args with
Con.Aux n -> assert false
| Con.Premise prem ->
(match prem.Con.premise_binder with
- None -> [B.Text([],"Contradiction, hence")]
+ None -> [B.b_kw "Contradiction, hence"]
| Some n ->
- [B.Object ([],P.Mi([],n)); B.skip;B.Text([],"is contradictory, hence")])
+ [ B.Object ([],P.Mi([],n)); B.skip;
+ B.b_kw "is contradictory, hence"])
| Con.Lemma lemma ->
- [B.Object ([], P.Mi([],lemma.Con.lemma_name)); B.skip; B.Text([],"is contradictory, hence")]
+ [ B.Object ([], P.Mi([],lemma.Con.lemma_name)); B.skip;
+ B.b_kw "is contradictory, hence" ]
| _ -> assert false) in
(* let body = proof2pres {proof with Con.proof_context = tl} in *)
make_row arg proof_conclusion
and andind conclude =
- let module P = Mpresentation in
- let module Con = Content in
let proof_conclusion =
(match conclude.Con.conclude_conclusion with
- None -> B.Text([],"No conclusion???")
+ None -> B.b_kw "No conclusion???"
| Some t -> term2pres t) in
let proof,case_arg =
(match conclude.Con.conclude_args with
None -> []
| Some n -> [(B.b_kw "by"); B.b_space; B.Object([], P.Mi([],n))])
| Con.Lemma lemma ->
- [(B.b_kw "by");B.skip; B.Object([], P.Mi([],lemma.Con.lemma_name))]
+ [(B.b_kw "by");B.skip;
+ B.Object([], P.Mi([],lemma.Con.lemma_name))]
| _ -> assert false) in
match proof.Con.proof_context with
`Hypothesis hyp1::`Hypothesis hyp2::tl ->
acontext2pres proof.Con.proof_apply_context body false in
B.V
([],
- [B.H ([],arg@[B.skip; B.Text([],"we have")]);
+ [B.H ([],arg@[B.skip; B.b_kw "we have"]);
preshyp1;
- B.Text([],"and");
+ B.b_kw "and";
preshyp2;
presacontext]);
| _ -> assert false
and exists conclude =
- let module P = Mpresentation in
- let module Con = Content in
let proof_conclusion =
(match conclude.Con.conclude_conclusion with
- None -> B.Text([],"No conclusion???")
+ None -> B.b_kw "No conclusion???"
| Some t -> term2pres t) in
let proof =
(match conclude.Con.conclude_args with
[presdecl;
suchthat;
presacontext]);
- | _ -> assert false in
+ | _ -> assert false
-proof2pres p
-;;
+ in
+ proof2pres p
-exception ToDo;;
+exception ToDo
let counter = ref 0
(match def_name with
None -> "_"
| Some n -> n)) ;
- B.b_text [] ":=" ;
+ B.b_text [] (Utf8Macro.unicode_of_tex "\\Assign");
term2pres bo]
| Some (`Proof p) ->
let proof_name = p.Content.proof_name in
(match proof_name with
None -> "_"
| Some n -> n)) ;
- B.b_text [] ":=" ;
+ B.b_text [] (Utf8Macro.unicode_of_tex "\\Assign");
proof2pres term2pres p])
(List.rev context)) @
- [ B.b_text [] "|-" ;
+ [ B.b_text [] (Utf8Macro.unicode_of_tex "\\vdash");
B.b_object (p_mi [] (string_of_int n)) ;
B.b_text [] ":" ;
term2pres ty ])))
(* Conjectures are in their own table to make *)
(* diffing the DOM trees easier. *)
[B.b_v []
- ((B.b_text []
- ("Conjectures:" ^
- (let _ = incr counter; in (string_of_int !counter)))) ::
+ ((B.b_kw ("Conjectures:" ^
+ (let _ = incr counter; in (string_of_int !counter)))) ::
(List.map (conjecture2pres term2pres) metasenv'))]
let params2pres params =
| `Inductive _ -> "Inductive definition"
| `CoInductive _ -> "CoInductive definition"
in
- B.b_h [] (B.b_text [] kind :: params2pres params)
+ B.b_h [] (B.b_kw kind :: params2pres params)
let inductive2pres term2pres ind =
let constructor2pres decl =
in
B.b_v []
(B.b_h [] [
- B.b_text [] (ind.Content.inductive_name ^ " of arity ");
+ B.b_kw (ind.Content.inductive_name ^ " of arity");
+ B.smallskip;
term2pres ind.Content.inductive_type ]
:: List.map constructor2pres ind.Content.inductive_constructors)
let name = get_name p.Content.proof_name in
B.b_v
[Some "helm","xref","id"]
- ([ B.b_h [] (B.b_text [] ("Proof " ^ name) :: params2pres params);
- B.b_text [] "Thesis:";
+ ([ B.b_h [] (B.b_kw ("Proof " ^ name) :: params2pres params);
+ B.b_kw "Thesis:";
B.indent (term2pres thesis) ] @
metasenv2pres term2pres metasenv @
[proof2pres term2pres p])
let name = get_name body.Content.def_name in
B.b_v
[Some "helm","xref","id"]
- ([B.b_h [] (B.b_text [] ("Definition " ^ name) :: params2pres params);
- B.b_text [] "Type:";
+ ([B.b_h [] (B.b_kw ("Definition " ^ name) :: params2pres params);
+ B.b_kw "Type:";
B.indent (term2pres ty)] @
metasenv2pres term2pres metasenv @
- [term2pres body.Content.def_term])
+ [B.b_kw "Body:"; term2pres body.Content.def_term])
| `Decl (_, `Declaration decl)
| `Decl (_, `Hypothesis decl) ->
let name = get_name decl.Content.dec_name in
B.b_v
[Some "helm","xref","id"]
- ([B.b_h [] (B.b_text [] ("Axiom " ^ name) :: params2pres params);
- B.b_text [] "Type:";
+ ([B.b_h [] (B.b_kw ("Axiom " ^ name) :: params2pres params);
+ B.b_kw "Type:";
B.indent (term2pres decl.Content.dec_type)] @
metasenv2pres term2pres metasenv)
| `Joint joint ->
(recursion_kind2pres params joint.Content.joint_kind
:: List.map (joint_def2pres term2pres) joint.Content.joint_defs)
| _ -> raise ToDo
-;;
-
-(*
-let content2pres ~ids_to_inner_sorts =
- content2pres
- (function p ->
- (Cexpr2pres.cexpr2pres_charcount
- (Content_expressions.acic2cexpr ids_to_inner_sorts p)))
-;;
-*)
let content2pres ~ids_to_inner_sorts =
content2pres
(fun annterm ->
- let (ast, ids_to_uris) as arg =
- Acic2Ast.ast_of_acic ids_to_inner_sorts annterm
+ let ast, ids_to_uris =
+ CicNotationRew.ast_of_acic ids_to_inner_sorts annterm
in
- let astBox = Ast2pres.ast2astBox arg in
- Box.map (fun ast -> Ast2pres.ast2mpres (ast, ids_to_uris)) astBox)
+ CicNotationPres.box_of_mpres
+ (CicNotationPres.render ids_to_uris
+ (CicNotationRew.pp_ast ast)))